Tobacco smoke exposure, the lower airways microbiome and outcomes of ventilated children

Leroue, Matthew K.; Williamson, Kayla; Curtin, Paul; Sontag, Marci K.; Wagner, Brandie D.; Ambroggio, Lilliam; Bixby, Moira; Busgang, Stefanie A.; Murphy, Sharon E.; Peterson, Lisa A.; Vevang, Karin R.; Sipe, Christopher J.; Harris, J. Kirk; Reeder, Ron; Locandro, Christopher; Carpenter, Todd; Maddux, Aline B; Simões, Eric A F; Osborne, Christina; Robertson, Charles E.; Langelier, Charles; Carcillo, Joseph A.; Meert, Kathleen L.; Pollack, Murray M.; McQuillen, Patrick S.; Mourani, Peter M.

doi:10.1038/s41390-023-02502-8

Cited by 4 publications

(3 citation statements)

References 42 publications

(64 reference statements)

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“…As emerging tobacco products like e-cigarettes increase in popularity, a key public health question involves how the respiratory effects of these alternatives compare to traditional cigarette smoking. Extensive epidemiologic evidence clearly links cigarette smoking to increased risks of COPD, including emphysema and chronic bronchitis (Leroue et al 2023). Cigarette smoke induces chronic inflammation and oxidative stress that damages alveoli, impairs mucociliary clearance, and disrupts normal lung architecture over time.…”

Section: Respiratory Effectsmentioning

confidence: 99%

Oxidative stress and inflammation: elucidating mechanisms of smoking-attributable pathology for therapeutic targeting

Addissouky,

El Sayed,

Ali

et al. 2024

Bull Natl Res Cent

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Background Tobacco smoking remains a major preventable cause of disease and death worldwide. Combustible cigarettes release thousands of chemicals that can initiate inflammatory pathways leading to smoking-related illness. This review aims to synthesize current scientific knowledge on mechanisms of smoking-induced disease, epidemiological trends, and clinical strategies from recent literature. Main body of the abstract At the cellular level, cigarette smoke triggers oxidative stress through reactive oxygen species (ROS), causing DNA damage. This provokes inflammatory signaling cascades mediated by damage-associated molecular patterns (DAMPs), receptors like RAGE and TLRs, and downstream cytokines. Smoking also disrupts apoptosis and autophagy. In the lungs, oxidative stress and inflammation from smoking play central roles in COPD pathogenesis. Smoking-induced oxidative DNA damage, chronic inflammation, and impaired immunity combine to promote lung carcinogenesis. For cardiovascular disease, smoking triggers endothelial dysfunction, platelet activation, and atherogenesis through oxidized LDL and effects on nitric oxide and adhesion molecules. Short conclusion Given the unequivocal evidence of health risks, smoking cessation is critical to reducing preventable death and disability. Both counseling and pharmacotherapy have proven efficacy for quitting, but efficacy remains limited long-term. Emerging nicotine products like e-cigarettes have unknown impacts on cessation and population health. Comprehensive efforts encompassing prevention, screening, treatment innovation, harm reduction, and policy reform focused on curbing smoking-attributable morbidity and mortality are warranted.

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Section: Respiratory Effectsmentioning

confidence: 99%

Oxidative stress and inflammation: elucidating mechanisms of smoking-attributable pathology for therapeutic targeting

Addissouky,

El Sayed,

Ali

et al. 2024

Bull Natl Res Cent

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“…These genera are also affected by active smoking and second-hand smoke (e.g., Corynebacterium, Staphylococcus, Streptococcus) (Kelley et al, 2021). Similarly, the abundance of Serratia, Moraxella, Haemophilus, and Staphylococcus aureus in tracheal aspirate changed after tobacco exposure (Leroue et al, 2023). The longitudinal effects of environmental tobacco smoke exposure on gut microbiota of young children have been previously reported.…”

Section: Impact Of Tobacco Smoke Exposure and Mercury On Gut Microbio...mentioning

confidence: 80%

Influence of perinatal and childhood exposure to tobacco and mercury in children’s gut microbiota

Pérez-Castro,

D’Auria,

Llambrich

et al. 2024

Front. Microbiol.

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BackgroundEarly life determinants of the development of gut microbiome composition in infants have been widely investigated; however, if early life pollutant exposures, such as tobacco or mercury, have a persistent influence on the gut microbial community, its stabilization at later childhood remains largely unknown.ObjectiveIn this exposome-wide study, we aimed at identifying the contribution of exposure to tobacco and mercury from the prenatal period to childhood, to individual differences in the fecal microbiome composition of 7-year-old children, considering co-exposure to a width of established lifestyle and clinical determinants.MethodsGut microbiome was studied by 16S rRNA amplicon sequencing in 151 children at the genus level. Exposure to tobacco was quantified during pregnancy through questionnaire (active tobacco consumption, second-hand smoking -SHS) and biomonitoring (urinary cotinine) at 4 years (urinary cotinine, SHS) and 7 years (SHS). Exposure to mercury was quantified during pregnancy (cord blood) and at 4 years (hair). Forty nine other potential environmental determinants (12 at pregnancy/birth/infancy, 15 at 4 years and 22 at 7 years, such as diet, demographics, quality of living/social environment, and clinical records) were registered. We used multiple models to determine microbiome associations with pollutants including multi-determinant multivariate analysis of variance and linear correlations (wUnifrac, Bray-Curtis and Aitchison ß-diversity distances), single-pollutant permutational multivariate analysis of variance adjusting for co-variates (Aitchison), and multivariable association model with single taxa (MaAsLin2; genus). Sensitivity analysis was performed including genetic data in a subset of 107 children.ResultsActive smoking in pregnancy was systematically associated with microbiome composition and ß-diversity (R2 2–4%, p < 0.05, Aitchison), independently of other co-determinants. However, in the adjusted single pollutant models (PERMANOVA), we did not find any significant association. An increased relative abundance of Dorea and decreased relative abundance of Akkermansia were associated with smoking during pregnancy (q < 0.05).DiscussionOur findings suggest a long-term sustainable effect of prenatal tobacco exposure on the children’s gut microbiota. This effect was not found for mercury exposure or tobacco exposure during childhood. Assessing the role of these exposures on the children’s microbiota, considering multiple environmental factors, should be further investigated.

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“…Epidemiologically, it is well known that smoking is a risk factor for the development of lung cancer. Smoking has been shown to alter the lung microbiome in mice [88], and children exposed to second-hand tobacco smoke had decreased alpha diversity and relative increases in Serratia spp., Moraxella spp., Haemophilus spp., and Staphylococcus aureus [89]. In adults, smoking is also known to alter the microbiome of the lungs, in particular, by enabling colonization by pathogenic bacteria and thus conferring an increased risk of infections [90].…”

Section: Smokingmentioning

confidence: 99%

The Complex Role of the Microbiome in Non-Small Cell Lung Cancer Development and Progression

Souza,

Forder,

Pewarchuk

et al. 2023

Cells

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In recent years, there has been a growing interest in the relationship between microorganisms in the surrounding environment and cancer cells. While the tumor microenvironment predominantly comprises cancer cells, stromal cells, and immune cells, emerging research highlights the significant contributions of microbial cells to tumor development and progression. Although the impact of the gut microbiome on treatment response in lung cancer is well established, recent investigations indicate complex roles of lung microbiota in lung cancer. This article focuses on recent findings on the human lung microbiome and its impacts in cancer development and progression. We delve into the characteristics of the lung microbiome and its influence on lung cancer development. Additionally, we explore the characteristics of the intratumoral microbiome, the metabolic interactions between lung tumor cells, and how microorganism-produced metabolites can contribute to cancer progression. Furthermore, we provide a comprehensive review of the current literature on the lung microbiome and its implications for the metastatic potential of tumor cells. Additionally, this review discusses the potential for therapeutic modulation of the microbiome to establish lung cancer prevention strategies and optimize lung cancer treatment.

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Tobacco smoke exposure, the lower airways microbiome and outcomes of ventilated children

Cited by 4 publications

References 42 publications

Oxidative stress and inflammation: elucidating mechanisms of smoking-attributable pathology for therapeutic targeting

Oxidative stress and inflammation: elucidating mechanisms of smoking-attributable pathology for therapeutic targeting

Influence of perinatal and childhood exposure to tobacco and mercury in children’s gut microbiota

The Complex Role of the Microbiome in Non-Small Cell Lung Cancer Development and Progression

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